JP3516490B2 - Line interface device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a line interface device, and more particularly to a broadband ISDN (B-ISDN: Broadb).
subscriber line and asynchronous transfer mode type (A-and-ISDN)
The present invention relates to a line interface device having an interface function with a TM switch module or an interface function between an ATM switch module and an interoffice transmission line (various switches such as a toll switch (Toll Switch)).

[0002]

2. Description of the Related Art Commercialization of a wideband ISDN (B-ISDN) has started, and nowadays it is in the stage of commercial development of an ATM exchange.

FIG. 9 shows an example of the configuration of a broadband ISDN system. In the figure, 80 to 82 are ATM exchanges. The ATM switches 80 to 82 are connected by a high-speed transmission line, for example, optical fiber transmission lines 801 to 803.
The exchange and the subscriber (user) are connected to the subscriber lines 804 to 807 through a subscriber exchange (Local Switch) 83 which is a concentrator or directly.

FIG. 10 shows an example of the structure of an ATM exchange.
ATM switch module 800 and subscriber (user)
And the ATM trunk line exchange are connected through a line interface device 90.

Here, the line interface device 90 and A
622 Mbp between the TM switch module 800
It is connected by a high-speed transmission line such as s. This transmission line speed is regulated by the ITU-T, Bell Core standard, or the like.

The line interface device 90 usually comprises a line terminating device and a line control device. The line terminating device uses a payload (P
The 53-byte ATM cell loaded on the (aload) is extracted.

The line controller, for this ATM cell, includes a virtual path identifier (VPI) included in the ATM cell.
And a virtual channel identifier (VCI), that is, a 1-byte stored in a table (not shown) for controlling route switching in the ATM switch module 800 based on a signal for identifying a virtual circuit on a physical circuit. It has a function of adding a route selection signal (TAG) and sending it to the ATM switch module 800.

On the other hand, the subscriber connected to the line interface device 90 is connected to a subscriber line transmission line of various speeds such as 45M to 622Mbps. Therefore, although details of the line interface device 90 are not shown in FIG. 10, a multiplex circuit (not shown) multiplexes a plurality of low-speed subscriber lines to connect to the ATM switch module 800. Interfaced with speed.

On the other hand, the subscriber line transmission line may have the same speed as the transmission line on the ATM switch module 800 side. In this case, the plurality of subscriber line transmission lines are interfaced with the transmission line side of the ATM switch module 800 without being multiplexed.

FIG. 11 shows the subscriber line transmission line as described above.
FIG. 3 is a diagram illustrating a connection relationship between the ATM switch module 800 in an ATM switch and a line terminating device and a line control device that form a line interface device in the case of having the same speed (622 Mbps) as the transmission path on the side of the ATM switch module 800. is there.

In FIG. 11, 800 (800 ') is
Redundant ATM switch module (# 0, # 1)
Is. Dual ATM switch module 800
Corresponding to (800 '), the duplicated line control device 92 (92') is connected to the inter-station transmission line (East side) on the subscriber line side (West side) and the trunk line exchange side.

Further, FIG. 11A shows the subscriber line side (West).
Side) to the inter-station transmission line (East side) on the trunk line exchange side, FIG. 11B shows the downlink from the inter-station transmission line (East side) on the trunk line exchange side to the subscriber line side (West side). Shows the direction.

In the example of FIG. 11, since the subscriber line is a single line, one line terminating device 91 is switched and connected to the line control device 92 (92 ') which is a working line and a backup line. On the other hand, in the inter-station transmission line on the side of the trunk switch of the ATM switch module 800 (800 ′), the duplicated line control device 92 (92 ′) is different from the duplicated line termination device 91 (9).
1 ') is connected.

The redundant line control device 92 (92 ') and the redundant line terminating device 91 (91') are cross-connected and switched according to the working / standby state.

The above-mentioned configuration is applied to the subscriber side (West).
Side) from the inter-station transmission line (East side) to the trunk line exchange side, and the inter-station transmission line (East side) to the relay line exchange side
Side) to the subscriber side (West side).

FIG. 12 shows a line terminating device 91 (91 ') which constitutes an ATM switch module 800 and a line interface device when the subscriber line transmission line is duplicated.
FIG. 6 is a diagram illustrating a connection relationship with a line control device 92 (92 ′).

Although the drawing shows only the upstream direction from the subscriber side (West side) to the inter-station transmission line (East side) on the trunk line exchange side, it is omitted as in the case of FIG. The same configuration is provided in the downlink direction from the inter-station transmission path (East side) on the trunk line exchange side to the subscriber side (West side).

In the case of FIG. 12, a pair of line terminators 91 (91 ') also correspond to the duplicated subscriber lines on the subscriber line side.
, And the line terminating device 91 (91 ′) is switched and connected to the line control device 92 (92 ′) according to the working / standby state. Other connection forms are the same as those shown in FIG.

FIG. 13 is a diagram showing a possible application form of the line interface device in the case where the subscriber side corresponds to FIG. In FIG. 13, two subscriber lines I and II, each of which has a speed of 622 Mbps, are individually duplicated through the line terminating device 91 (91 ') in the interface device surrounded by broken lines. )It is connected to the.

In FIG. 14, the subscriber side corresponding to FIG.
It is a figure which shows one assumed application form of the line interface apparatus in case of +1 duplexing. In FIG. 14, the duplicated subscriber lines I and I ′ are connected to the corresponding line terminators (a) 91 and (b) 91 ′, respectively.

Further, these line terminators (a) 91,
(B) 91 'is configured to be connected to the duplicated line control device 92 (92'). Then, in FIG. 14, the line control device 92 (92 ') selects the main signal on the working line of the duplicated subscriber lines I and I'and selects ATM.
It is sent to the switch interface 800 (800 ') side.

Here, the line controller 92 (92 ') in FIGS. 13 and 14 is configured as shown in FIG. In FIG. 15, the line controller 92 includes select gates 920 and 921, a control circuit 922, a signal circuit 923,
Multiplexing circuit 924 for inserting the intra-station communication signal from the signal circuit 923 into the main signal, ATM switch module 800
Branch circuit 9 for branching the intra-station communication signal from (800 ')
25 and a virtual channel converter (VCC) 925 for inserting a TAG signal for controlling the route selection in the ATM switch module 800.

Under the control of the control circuit 922, the selection gate 920 switches and outputs the main signal on the working side of the pair of line terminators 91 (91 '). The main signal from the ATM switch module side is a pair of line terminator 91 (91 ').
Is commonly output to.

Further, the selection gate 921 has a function of returning the main signal from the ATM switch module side under the control of the control circuit 922 in the loopback test.

In the form of the single duplexed line of FIG. 13 and the form of the 1 + 1 duplex of FIG. 14, the individual line controllers are:
The configuration is as shown in FIG. However, the control circuit 9
22 and the signal circuit 923 commonly function and can be used for switching the main signal.

Therefore, in each of the line control devices,
It is not always necessary to provide the control circuit 922 and the signal circuit 923, and the configuration of FIG.
If it is used for, the circuit configuration becomes redundant, which goes against the demand for downsizing of the device.

Further, in the case where the apparatus configuration of 1 is used by switching between the single-duplex line form of FIG. 13 and the 1 + 1 duplex form of FIG. 14, when the 1 + 1 duplex form is set as shown in FIG. Then, the line controller 92 (92 ') shown by the broken line remains unused.

Furthermore, as is apparent from FIGS. 11 and 12, the ATM switch module 800 (800 ').
A line interface device provided on the subscriber line side of
It is possible to have the same configuration as the line interface device provided in the inter-station transmission line on the trunk line exchange side of the ATM switch module 800 (800 ′). Generally, the subscriber line transmission line has a single structure and the inter-station transmission line has a double structure.

[0029]

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to make the line control devices connected to the inter-station transmission lines on the subscriber side and the trunk line exchange side of the ATM switch module have the same structure. A that enables cost reduction
It is to provide a line interface device for a TM switch.

Further, an object of the present invention is that it can be used by switching between a single-duplex double line form and a 1 + 1 single-line form, and a part of the control circuit or the like is shared in the working / spare,
It is an object of the present invention to provide a line interface device for an ATM exchange that enables cost reduction and device miniaturization.

Still other objects of the invention will be apparent from the following detailed description and claims.

[0032]

A line interface device for an exchange according to the present invention is a line interface device for interfacing a switch module and a subscriber line, and has a transmission speed equivalent to that of a transmission line of the switch module. A plurality of line terminators for terminating the subscriber line having a transmission speed; and a line controller for accommodating a plurality of transmission lines of a switch module and having a line processing circuit corresponding to the plurality of lines. , Each of the plurality of line terminators corresponds to each of the plurality of lines,
Use the line as a single line, or use two of the plurality of line terminators as a set and use one of the line processing circuits corresponding to the set as a 1 + 1 double line. It is configured to be switchable.

As described above, in the present invention, since one line control device can be used as a single line or double line, the cost of the device can be reduced.

The line interface device of the present invention is
As an extension of the above configuration, one of the line processing circuits corresponding to the plurality of lines is used as a standby line, and n:
It is configured to be used for 1 duplex line.

Further, as a specific mode of the present invention, the line processing circuit of the line control device has a selection gate, and
It is configured to control the connection with the transmission line of the switch through the selection gate for the line terminators in each set.

Further, specifically, when the line is used as a single line, the select gate connects each of the two line terminating devices to a separate transmission line of a switch. When the line is used as a 1 + 1 duplex line, it is controlled so that each of the two line terminators in each pair is connected to a common transmission line of a switch.

Further, the interface device of the present invention is further provided with a control circuit for controlling the selection gate and a signal circuit for transmitting / receiving an intra-station communication signal in common to the plurality of line processing circuits. As a result, the control circuit and the signal circuit can be commonly used for a plurality of lines. Therefore, the size of the device can be reduced and the cost can be reduced.

Furthermore, the line interface device of the present invention has the same configuration as that described above, is provided on the opposite side of the switch module from the subscriber transmission line, and provides an interface between the switch module and the trunk line exchange. Configured to take. As a result, a line interface device having a common configuration can be used to interface the switch module with the subscriber transmission line and the interface between the switch module and the trunk switch. Thereby, the cost of the device can be further reduced.

[0039]

EXAMPLES Examples will be described below with reference to the drawings. In the following drawings, the same or similar parts will be described with common reference numerals and symbols.

FIG. 1 is a block diagram for explaining the principle of the present invention in a form in which an exchange including a line interface device according to the present invention is applied to a single double line. In the figure, 9 is a line interface device according to the present invention, and subscriber lines I and II for two lines are connected to a line terminating device (a) 910 and a line terminating device (b) 911, respectively.

The line terminating device (a) 910 and the line terminating device (b) 911 are then duplicated in the line controller 9.
2 (92 '). Line control device 92 (9
2 ') is connected to the further duplicated ATM switch module 800 (800').

Here, comparing with the application form of FIG. 13 ,
In FIG. 13 , two sets of separate redundant line control devices 92 (92 ′) are provided for the line termination devices 910 ( 910 ′ ) connected to the subscriber lines I and II. Then, this is standardized and integrated in one device.

As a result, the control circuit 922 and the signal circuit 9
The portion 23 (see FIG. 13 ) is shared by the pair of line control devices 92 (92 ′) in FIG.

On the other hand, FIG. 2 is a principle block diagram for explaining an application form of the 1 + 1 duplexing of the line interface device according to the present invention. Similarly, in the figure, 9 is a line interface device, which is a dual subscriber line I.
(I ') is a duplexed line termination device 91 (91')
It is connected to the.

Further, the pair of line terminating devices 91 (91 ') for working (a) / standby (b) are integrated and connected to the duplicated line controller 92 (92').

The line control device 92 (92 ') switches and selects the main signal from the output of the line terminating device 91 (91') corresponding to the working subscriber line, and the ATM switch interface 800 (800). ').

Here, the line control device 92 (9
2 ') is the same as that of the line controller 92 (92') in FIG. 1, but in the case of 1 + 1 duplexing, the line controller 92 (92 ') in FIG. Circuit is used.

In the present invention, as is apparent from FIGS. 1 and 2, the line control device 92 (92 ') is a single unit.
It is commonly used in the case of the line and the case of the duplication of 1 + 1. Furthermore, in comparison with FIG. 13 and FIG.
The control circuit 922 and the signal circuit 923 are commonly used for a plurality of lines in one line control device 92 (92 ′).

Therefore, the line controller 92 (92 ')
It is possible to reduce the hardware scale of. As a result, the number of lines accommodated in the shelf can be increased, and the cost per line can be reduced.

FIGS. 3 and 4 can commonly correspond to the modes of FIGS. 1 and 2, respectively, and are respectively connected to the subscriber line side (West) of the duplexed ATM switch module 800 (800 ').
Side) and a relay switching center side (East side). FIG.

Further, in the examples of FIGS. 3 and 4, in the case of a single line connection, the subscriber lines for four lines are connected, and in the case of a dual line, the subscriber lines for two lines are 1 + 1. A redundant pair of.

In FIG. 3, the east side of the duplexed line control device 92 (92 ') is connected to the AT through the lines A to D.
M switch module 800 (800 ') is connected,
On the West side, a line terminating device 910 to which a subscriber line is connected
~ 913 are provided.

On the contrary, in FIG. 4, the ATM switch module 800 (800 ') is connected to the west side of the line control device 92 (92') of the duplicated configuration through the lines A to D, and the east side is connected to the relay exchange. Line control devices 910 to 913 for interfacing are provided.

As described above, the configurations of FIGS. 3 and 4 are the same except that the directions of the main signals are inverted. Therefore, the details will be described centering on the configuration of FIG.

In FIG. 3, the line controller 92 (9
2 ') has select gates 920, 9 facing the East side.
21, 923, 920 ', 921', 923 'and We
It has select gates 924 and 924 ′ that face the st side.

Further, select gates 925 and 92, respectively.
Virtual channel conversion circuit (VC) to which the outputs of 6, 925 'and 926' are input.
C) 925, 926, 925 'and 926' are connected.

Virtual channel conversion circuit (VCC) 925,
As will be described later, 926, 925 ′, and 926 ′ are VCIs (virtual channel identifiers) that specify virtual channels and paths on the physical lines included in the ATM cells extracted by the line terminators 910 to 913. ) Or VPI (virtual path identifier) based on the ATM switch module 8
This is a circuit for inserting a tag (TAG) for performing route setting (routing) at 00 (800 ').

Further, the line controller 92 (92 ') has
A common multiplexing circuit 927 and demultiplexing circuit 928 are provided. The multiplexing circuit 927 adds the intra-station communication signal from the signal circuit 929 to the main signal from the VCC circuit 925,
Output to the switch module 800 (800 ') side.

The separation circuit 928 separates the intra-station communication signal from the ATM switch module 800 (800 ') side and inputs it to the signal circuit 929. Further, switching of each of the above selection gates is performed by the control circuit 930 based on signaling control described later.

One control circuit 930 is commonly provided for controlling the above selection gates. Also,
In the signal circuit 929, the ATM switch module 8
The transmission and reception of the intra-station communication signal with the 00 (800 ') side are commonly performed. Therefore, the signal circuit 929 can also be configured by one common circuit like the control circuit.

As described above, the configuration of the line control device in the line switch interface 800 (800 ') according to the present invention is smaller than that of FIGS. 13 and 14 because the control circuit 930 and the signal circuit 929 are shared. Is possible.

In the configuration shown in FIGS. 3 and 4 as described above,
The operation when the line control devices 92 and 92 'are used for the single 4 lines corresponding to FIG. 1 for explaining the single 2 lines will be described.

In FIG. 3, line terminators 910-91.
3 to 4 subscriber lines are connected. That is, 910
Reference numeral 913 is a line terminating device connected to the respective subscriber lines corresponding to the four subscriber lines.

The main signal sent from the subscriber line connected to the line terminating equipment 910 in the upstream direction (direction from the subscriber line to the ATM switch module) is the selection gate 920.
921, TAG is added by the VCC circuit 925,
The intra-station communication signal from the signal circuit is added and sent to the line A of the ATM switch module 800 (800 ′).

Similarly, the main signal sent in the upstream direction from the subscriber line connected to the line terminator 911 is the selection gate 9
23, a TAG is added by the VCC circuit 926, and A
It is sent to the line B of the TM switch module 800 (800 ').

Further, the main signal sent from the subscriber line connected to the line terminating equipment 912 in the upstream direction is the selection gate 92.
0 ', 921', a TAG is added by the VCC circuit 925 ', and the ATM switch module 800 (80
0 ') is sent to the line C.

Similarly, the main signal sent from the subscriber line connected to the line terminating device 913 in the upstream direction passes through the selection gate 923 ', the TAG is added by the VCC circuit 926', and the ATM switch module 800 ( 800 ')
It is sent to the track D.

On the contrary, the ATM switch module 800
The main signals sent in the downstream direction from the lines A to D of (800 ′) are directly transmitted to the line terminators 910 and 912 from the lines A and C, respectively, and the line terminators 911 and 913.
To the selection gates 924 and 92 from the lines B and D, respectively.
Sent through 4 '.

On the other hand, when the line controller of FIG. 3 is applied to the 1 + 1 duplex mode corresponding to FIG. 2, line controllers 910 and 911 and line controller 9 of FIG.
12 and 913 respectively form a duplication set (pair).

Therefore, the line terminators 910 and 911.
The two subscriber lines connected to each other are working / standby lines connected to one subscriber and transmitting the same main signal. Similarly, the two subscriber lines connected to the line terminators 912 and 913 are also working / standby lines connected to one subscriber and transmitting the same main signal.

That is, when the subscriber line connected to the line terminators 910 and 912 is in use, the line terminators 910 and 9 are used.
The outputs from 12 are selected by the selection gates 920 and 920 'and sent to the lines A and C on the ATM switch module side, respectively.

On the other hand, ATM switch module 800
The input from the line A on the (800 ') side is the line terminating device 9
Commonly sent to 10 and 911. The input from the line C on the ATM switch module 800 (800 ′) side is commonly sent to the line terminators 912 and 913.

3 and 4, the selection gate 92
1, 921 'are ATM switch modules 800 (8
The signal from 00 ') is looped back and used for loopback testing.

FIG. 5 shows SONE proposed by the former AT & T company.
It is a T (synchronous optical communication network) frame format, and is composed of one row of 1080 bytes × 9 rows. Line terminator 9
10 to 913 extract the 53-byte ATM cell placed in the payload area P of this frame format and input them to the line control devices 92 and 93.

The 53-byte ATM cell is used in the VCC circuit 925 (92) in the line controller 92 (92 ').
5 ', 926, 926') is a 1-byte tag (TA
G) is added.

In FIG. 6, for the ATM cells in the frame format P, the VCC circuit 925 (925 ', 926, 92) is further provided in the line controller 92 (92').
6 ') is a format in which a 1-byte tag (TAG-A to C) is added. Therefore, in FIG. 8, the ATM cell has 54 bytes.

FIG. 7 shows the structure of the ATM switch module, and is a diagram for explaining the signal control in the switch in particular. In FIG. 7, reference numerals 910 and 911 denote the line terminating devices described in FIG. 3, reference numeral 92 denotes a main function unit of the line control device, and 922 is a control circuit in the line control device 92.

Reference numerals 801 and 802 denote upstream and downstream cross switch sections of the ATM switch module 800, respectively. In this cross switch section, route selection switching is performed according to the tag (TAG) included in the ATM cell. Further, 803 and 804 are wide band signal control units (BSGC), and 805 is a wide band call processor (BCPR).

Broadband Call Processor (BCPR) 805
Has a function of storing the OS (operation software) and executing control of the entire system. Wideband signal control units (BSGC) 803 and 804 are provided in the ATM switch module 800 (800 ′), and
It has a high level data link control processing function (HDLC) for TM cells.

Wideband signal controller (BSGC) 803, 8
04 is controlled by a Broadband Call Processor (BCPR) 805 and is also a Broadband Call Processor (BCPR) 805.
And the intra-station communication between the line control device 92 (92 ').

FIG. 8 shows an operation sequence of the line controller 92 (92 '). Broadband Call Processor (BCPR)
Broadband signal controller (BSGC) according to the OS of 805
The intra-station communication signal is transmitted and received between 804 (see FIG. 7) and the control circuit 930 of the line control device 92 (92 ′).

According to this intra-station communication signal, the above-mentioned single / duplex mode of the system is set. That is, in FIG. 8, when the power is turned on, the control circuit 930 in the line control device 92 (92 ′) first conducts a self-test of each function.

In FIG. 8, a ₁ is a line controller 92.
In (92 '), a part forming a system connected to the line A, b ₁ is a part forming a system connected to the line B, and a ₂ is a part forming a system connected to the line C. b
Reference numeral ₂ is a portion forming a system connected to the line D.

When the self test is completed, the control circuit 93
By the control from 0, the autonomous initialization of the device for the above a ₁ , b ₁ , a ₂ , b ₂ is performed. Then, the broadband signal control unit (BSGC) 804 of the ATM switch module 800 (800 ′) sends a request for establishing an intra-station communication link to the control circuit 930 under the control of the broadband call processor (BCPR) 805 based on the OS.

Upon receipt of this intra-station communication link establishment request,
From the control circuit 930 through the signal circuit 929, the link establishment response as the intra-station communication signal is added to the main signal as a multiplexing circuit 927.
And sends it to the ATM switch module 800 side.

The link establishment response is received by the broadband signal controller (BSGC) 804 of the ATM switch module 800. Next, wideband signal controller (BSGC)
The initial setting signal from 804 is the broadband signal control unit (BSG
C) Sent from 804 to the control circuit 930 of the line controller 92.

This initial setting signal includes a single / duplex switching control signal. Therefore, the control circuit 93
Upon receiving the initial setting signal, 0 multiplexes the confirmation signal ACK into the main signal as an intra-station communication signal, and returns the multiplexed signal to the broadband signal control unit (BSGC) 804. At the same time, according to this initial setting signal, the above-mentioned respective systems a ₁ , b ₁ , a ₂ , b
_{2 is set} to be a single or double mode.

The setting of the single or double mode is performed by selecting the selection gates 920, 920 'and 92 of the line controller 92 (92') shown in FIGS. 3 and 4 as described above.
This is performed by switching 4, 924 'at the timing of ● in FIG.

Before the switching control signal for setting the single mode or the dual mode is received, the select gates 920, 9 are operated so as to operate in the dual mode as a default.
20 ', 924, and 924' are switching-controlled.

When the setting of each system is completed, the fact is notified to the wide band signal controller (BSGC) 804.

In the above embodiment, in the case of the unification, the case where four subscriber lines are connected has been described, but the present invention is not limited to this, and (n + 1) subscriber lines are connected. It is also possible to connect to the line controller. This case can be applied to an n: 1 duplex line.

[0092]

As described above according to the embodiments,
The line interface device according to the present invention has a line terminating device and a line control device, and the line control device can adopt a common device configuration even when switching to single and dual.

Further, the line control devices provided in the inter-station transmission lines on the subscriber line side and the trunk line exchange side of the ATM switch moschul can also have the same configuration. Therefore, it is possible to reduce the size of the device and reduce the cost of the system.

[Brief description of drawings]

FIG. 1 is a diagram for explaining an application mode of a single line of a line interface device of the present invention.

FIG. 2 is a diagram for explaining an application mode of 1 + 1 duplexing of the line interface device of the present invention.

FIG. 3 is a block diagram of a configuration example of a line interface device on the subscriber line side.

FIG. 4 is a block diagram of a configuration example of a line interface device of an inter-station transmission line on the trunk line exchange side.

FIG. 5 is a diagram illustrating a frame format of a signal.

FIG. 6 is a diagram illustrating an ATM cell format.

FIG. 7 is a block diagram of a configuration example of an ATM interface module.

FIG. 8 is an operation sequence chart of the line control device.

FIG. 9 is a diagram illustrating an outline of a wideband ISDN system configuration.

FIG. 10 is a diagram illustrating an outline of a configuration of an ATM exchange.

FIG. 11 is a diagram illustrating an example of unification of subscriber lines.

FIG. 12 is a diagram illustrating an example of subscriber line duplication.

[Fig. 13] Fig. 13 is a diagram for describing an application form of a single line of a line interface device.

[Fig. 14] Fig. 14 is a diagram for explaining an application form of 1 + 1 duplexing of the line interface device.

FIG. 15 is a block diagram of a configuration example of a conventional line interface device.

[Explanation of symbols]

9 line interface device 92, 92 'line control device 800, 800' ATM switch 91, 91 ', 910, 911, 912, 913 line termination device 920, 921, 923, 924 select gate 929 signal circuit 930 control circuit 926 VCC ( Virtual channel conversion circuit)

Claims (4)

(57) [Claims] 1. A line interface device for interfacing between the switch module and the subscriber line, a plurality of line termination for terminating the subscriber line having a transmission rate equal to the transmission rate of the transmission path of the switch module A device and a plurality of transmission lines of the switch module are accommodated , each of which corresponds to each of the plurality of lines.
Insert the tag signal to set the route in the module.
And a one line control apparatus having a plurality of line processing circuit including a circuit for input, the plurality of each of the line termination device to correspond to each of the plurality of lines, the unification line each line of said plurality of lines Used as
And, or, as a two by a set of said plurality of line terminal, one by the two of said lines processing circuits corresponding to said set
Using a set of one use as 1 + 1 duplex line
Configured to be switched to, said circuit processing circuit further comprises a select gate, said two a time until
For the line terminators that are in one set,
To control the connection to the transmission line of the switch module.
It is configured to Gosuru further control circuit and station communication signal for controlling the said selection gate
A signal circuit for transmitting and receiving the signal is shared between the plurality of line processing circuits.
A line interface device characterized by being prepared for communication . 2. The transmission line connected to one line processing circuit among the plurality of line processing circuits corresponding to the plurality of lines is a standby line, and an n: 1 duplexed line is set forth in claim 1. A line interface device characterized by being used for. 3. The selection gate according to claim 1 , wherein when the line is used as a single line, each of the two line terminating devices in the switch module is provided as a separate transmission line of the switch module. Connect to
When the line is used as a 1 + 1 duplex line,
Line interface unit, characterized in that it is controlled so as to connect each of the line termination device which is the two by two sets to a common transmission path of the Sui <br/> pitch module. 4. has the configuration of a line interface device according to any one of claims 1 to 3, wherein the switch module and is configured to interface with the trunk exchange line Interface device.